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g4flukacomp [2011/11/12 09:19] – created 134.84.75.248g4flukacomp [2011/11/12 13:43] (current) 134.84.75.248
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-==introduction==+===introduction===
  
 A study is ongoing to try to understand the specific differences between FLUKA and Geant4 simulations.  Comparison to data are pursued wherever possible, although data is difficult to produce and not very abundant at present.  A study is ongoing to try to understand the specific differences between FLUKA and Geant4 simulations.  Comparison to data are pursued wherever possible, although data is difficult to produce and not very abundant at present. 
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     * Geant4.9.3+: this is a version of Geant4 which is Geant4.9.3 with the "shielding" physics list (implemented in v4.9.4) and a new muon-nuclear interaction (to be implemented in v4.9.5) have been backported     * Geant4.9.3+: this is a version of Geant4 which is Geant4.9.3 with the "shielding" physics list (implemented in v4.9.4) and a new muon-nuclear interaction (to be implemented in v4.9.5) have been backported
     * FLUKA 2011.2.5     * FLUKA 2011.2.5
 +
 +==geometry==
 +
 +==materails==
 +
 +==plots==
 +
 +Several of the more important plots can be viewed below in separate sections and additional plots are available [[:G4FlukaComp:additionalplots|here]].
 +
 +===muon primaries===
 +
 +==capture plots==
 +
 +For the scintillator material composed of C<sub>9</sub>H<sub>12</sub> which has density 0.887 g/cm<sup>3</sup> which is similar to the
 +Borexino scintillator, several plots have been produced.
 +
 +Several of the more important plots can be viewed below and additional plots are available [[:G4FlukaComp:additionalplots|here]].
 +
 +  for 280 GeV muons the time to capture on hydrogen is plotted below
 +  
 +{{:gfcompare:capture:gfn3times.png?500|Time since first muon hit for neutron captures on hydrogen. Muons start at 280 GeV.}}
 +
 +  for 280 GeV muons the radius at which the hydrogen capture takes place is plotted below, the distance is computed from the axis of the cylinder
 +  
 +{{:gfcompare:capture:gfn3pos.png?500|Position from muon axis for neutron captures on hydrogen. Muons start at 280 GeV.}}
 +
 +  for 280 GeV muons the multiplicity within each event of hydrogen captures is plotted below
 +  
 +{{:gfcompare:capture:gfn3mult.png?500|Multiplicity of neutron captures on hydrogen. Muons start at 280 GeV.}}
 +
 +==energy flux==
 +
 +As muons propagate through a cylindrical volume they begin creating neutrons and eventually the flux through the cylindrical area comes to constant.  This means in the first small percentage of the cylinder the flux is increasing and after that one can reliably extract the flux.  Below we plot the integrated
 +flux (over the whole 10m sensitive cylinder) as a function of energy.
 +
 +Several of the more important plots can be viewed below and additional plots are available [[:G4FlukaComp:additionalplots|here]]
 +
 +  for 280 GeV muons and Borexino scintillator we plot the integrated flux as a function of energy
 +  
 +{{:gfcompare:flux:nflux_myscintc9h12_mu_280gev.png?1000|Integrated flux for 280 GeV muons in scintillator.}}
 +
 +  for 100 GeV muons and lead we plot the integrated flux as a function of energy
 +  
 +{{:gfcompare:flux:nflux_mylead_mu_100gev.png?1000|Integrated flux for 100 GeV muons in Lead.}}
g4flukacomp.1321111146.txt.gz · Last modified: 2011/11/12 09:19 by 134.84.75.248

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